Technical field
[0001] The present invention relates to the field of cell biology and cell culture. It more
particularly relates to inserts used together with microwell plates to perform various
biological experiments.
State of the art
[0002] In vitro models of biological barriers (such as lung, skin, the intestines and the
blood-brain barrier) are used, for example, to screen potential pharmaceuticals and
toxins for their ability to enter into and to move around the human body. In vitro
models consist of a single layer or multiple layers of cells that are cultured in
the laboratory so as to mimic the properties of biological barriers in the body.
[0003] The function of biological barriers in the body is to divide the inside of the body
from the outside (e.g skin, lungs, the intestines) or different compartments of the
body from each other (e.g. the blood-brain barrier, the walls of blood vessels). In
order to model this function in the laboratory, in vitro models of biological barriers
are cultured on porous membranes. This is commonly done using microporous well inserts.
[0004] The well insert is used in combination with a microwell plate consisting of a number
of wells made in plastic. The insert is inserted into a well, which it divides in
two, a top (apical) compartment and a bottom (basolateral) compartment which communicate
via a porous membrane at the bottom of the insert. Cells are added to the apical side
of the well insert and are cultured on the porous membrane. Typically, the cells will
grow to form a watertight layer that divides the apical from the basolateral compartment,
as in the body.
[0005] The porous membrane is usually made of polymers or of inorganic aluminium oxide.
It is welded, moulded or glued to the wall of the insert, so as to obtain a perfect
seal. Indeed, it is necessary that the exchanges of material between apical and basolateral
compartments take place only through the microporous membrane and the cell layer upon
it. The membrane and the insert form a disposable assembly.
[0006] To study, for example, pharmaceutical drug transport or permeation across the model
biological barrier, candidate drugs are added to the apical compartment, which represents
the outside of the body for a skin model, or the inside of the lungs, or of the intestines,
etc.... Permeation is quantified by measuring the concentration of the candidate drug
in the basolateral compartment, which represents the inside of the body, after a fixed
time.
[0007] Recently, a new type of porous substrate has been developed using microfabrication
technology. Such substrates are fabricated by first depositing a thin layer of ceramic
material, such as Si
3N
4, on a silicon wafer. Pores are then etched in the Si
3N
4 by photolithography followed by a dry etch. The silicon wafer is then etched from
the other side to remove the entire thickness of silicon in selected areas, leaving
a set of supports for the transparent porous substrate that remain after removal of
the silicon. The resulting porous substrate comprises a silicon nitride membrane supported
on a silicon frame which gives it suitable mechanical properties.
[0008] Some advantageous of this type of porous substrates in comparison with other membranes,
are listed hereafter:
- much thinner membranes (less than 1 micrometer thick) can be fabricated, namely at
least 20 times thinner than the commonly- used membranes in commercial well inserts;
- pore sizes, shapes, densities and distributions in the membrane can be tuned as desired;
- the membrane is highly transparent in both air and water independently of the pore
size and density;
- the membranes are resistant to acids, bases, solvents, high temperatures and e-beam
exposure;
- the membranes are reusable (reconditionable) after cell culture.
These properties are available advantageously in one unique combination together with
the properties commonly exhibited by the existing membranes such as:
- low intrinsic fluorescence of the membrane;
- possible chemical pretreatment to enhance cell culture
- good cell growth in general and, in particular, the formation of tight layers of epithelial
cells;
- they withstand common sterilization procedures.
[0009] However, this kind of substrate presents two major drawbacks. Firstly, it is more
expensive than the commonly used polymer microporous substrates. This can be overcome
by its reuse. In addition, it requires a specific holder that makes it compatible
with a commercial well plate and also with routine laboratory practice.
[0010] Thus, the present invention aims to alleviate these problems and allow a practical
use of this type of substrate.
Summary of the invention
[0011] To this end, the invention concerns a clamping insert for cell culture comprising:
- a lower support comprising:
i. a hollow member sized to be engaged in a well of a microplate, said hollow member
being open at its both ends and comprising a support surface at one of its ends,
ii. first tightening means,
- an inner holder sized to be fitted inside the hollow member, and comprising second
tightening means arranged to cooperate with said first tightening means of the hollow
member to tighten reversibly between the inner holder and the support surface of the
lower support a porous substrate, said inner holder comprising an open channel keeping
free the porous substrate;
- retaining means intended to cooperate with the well of the microplate to allow the
clamping insert to be suspended in the well of the microplate,
- sealing means to hermetically seal the contact area between the inner holder and said
porous substrate.
[0012] Some other advantageous characteristics are specified in the claims.
[0013] The invention also concerns an assembly comprising such a clamping insert and a porous
substrate. The invention also concerns a method for clamping a porous substrate with
such an insert. Said method comprises the following steps:
- unfitting the inner holder and the lower support,
- placing said porous substrate on the support surface of the lower insert,
- disposing the inner holder so as to clamp the porous substrate between the inner holder
and the lower support,
- tightening the inner holder in the lower support.
[0014] A dedicated tool comprising some driving structures intended to cooperate with corresponding
structures arranged in the inner holder may be used for the tightening step if appropriate.
Brief description of the figures
[0015] The accompanying drawings, which are incorporated in and constitute a part of this
specification, illustrate embodiments of the invention, and, together with the general
description of the invention given above, and the detailed description of the embodiments
given below, serve to explain the principles of the present invention.
[0016] Figures 1 a and 1 b are two perspective views of an embodiment of the lower support,
figure 1c represents an anti-wear ring intended to cooperate with the lower support.
[0017] Figures 2a and 2b are two perspective views of an embodiment of the inner holder,
figure 2c represents a seal intended to cooperate with the inner holder.
[0018] Figure 3 show the assembled clamping insert according one embodiment of the invention.
[0019] Figure 4 represents an example of an assembling/disassembling tool adapted to the
invention.
[0020] Figure 5 and 6 propose sketches of two other embodiments of the invention.
Detailed description
[0021] Figures 1, 2 and 3 represent a preferred embodiment of an insert according to the
invention. This insert aims to facilitate the use as a biological substrate of a porous
substrate made with a Si
3N
4 layer deposited on a silicon wafer and then micromachined. Such a porous substrate
10 can be seen on figures 5 and 6. This substrate as such is not part of the invention
and will not be described in detail. One can refer to
Madou, M. J, Fundamental of Microfabrication and Nanotechnology, Second Edition,
CRC Press 2002, for more information about this technology.
[0022] It should be noticed that, due to specifications and costs of the substrate, it should
preferably be arranged in a reusable way.
[0023] Thus, to this end, the insert according to the invention comprises a lower support
12 (figures 1a and 1b) comprising a hollow member 14 sized to be engaged in a well
of a microplate, preferably of a standard microplate. The hollow member 14 could be
made in different suitable materials, like plastic or aluminium. PEEK (polyether ether
ketone), PC (polycarbonate), polystyrene or similar polymers are well suited since
they resist typical sterilization conditions and they can be injection moulded in
a low-cost production process.
[0024] The hollow member 14 is open at both its ends. At one end, its wall defines a reverse
side which forms a support surface 16 for the porous substrate 10. The lower support
12 furthermore comprises some flanges 18 extending from the wall of the hollow member
14 oppositely to the end comprising said support surface 16. These flanges 18 define
retaining means. They are sized and arranged so as to allow the lower support 12 and
the whole insert to rest on the sides of the microplate well and so as to avoid the
whole assembly touching the bottom of the microplate well.
[0025] The lower support 12 furthermore comprises first tightening means. In the detailed
example, these first tightening means take shape of two grooves 20, diametrically
opposed. Each groove 20 comprises a first longitudinal part, parallel to the longitudinal
axis of the cylinder of the hollow member 14. This first longitudinal part is extended
by a second inclined part, essentially perpendicular to the longitudinal axis but
with a slight slope directed toward the support surface 16.
[0026] The insert according to the invention comprises furthermore an inner holder 22 (figures
2a and 2b) sized to be adjusted inside the hollow member 14. More precisely, the inner
holder 22 is similar to the hollow member 14, the exterior dimension of which being
slightly lower than the interior dimensions of the hollow member 14. In this example,
the inner holder 22 has a cylindrical shape. This inner holder 22 can be made of plastic,
especially PEEK (polyether ether ketone), PC (polycarbonate), polystyrene or the like.
[0027] The inner holder 22 comprises second tightening means arranged to cooperate with
the first tightening means. In this example, said second tightening means are two
pins 24 diametrically opposed and sized to be engaged in the grooves 20 of the hollow
member 14, so as to form a bayonet fitting. The pins 24 and grooves 20 could also
be disposed reversely. A torque limiting system could be implemented so as to avoid
damaging the porous substrate.
[0028] The length of the inner holder 22 is sized so that, when the inner holder 22 is tightened
on the lower support 12, a porous substrate 10 may be clamped between both of them.
[0029] Thus, there may remain a free space between the support surface 16 and the end of
the inner holder 22, with a height lower than the thickness of the porous substrate.
When present, the porous substrate is held firmly in this free space. To decrease
the pressure and/or improve the clamping, interfaces can be fitted with suitable coatings
in rubber, Teflon or other elastic materials which will also reduce wear.
[0030] As explained above, it is of utmost importance that apical and basolateral compartments
be well separated so that exchanges between them be only implemented through the substrate
and the cells grown on it.
[0031] For this purpose and according an advantageous aspect of the invention, the insert
includes a sealing means to hermetically seal the contact area between the inner holder
22 and said porous substrate. One could also consider disposing the seal 26 between
the substrate end the lower support 12. Figures 5 and 6 show that it is possible to
dispose two seals, one on each side of the porous substrate 10.
[0032] For example, sealing means may be implemented with a silicone ring 26 (figure 2c)
interposed between the inner holder 22 and the porous substrate 10. Other suitable
materials may be used for the seal 26, like rubber or elastic polymers.
[0033] An annular recess may be also engraved in the substrate, in which the seal may take
place. Thus, the seal 26 is perfectly positioned and the tightness area is perfectly
defined around the porous membrane and the culture zone.
[0034] The insert according to the invention may also present some interesting and advantageous
features.
[0035] For instance, the lower support 12 may comprise grooves 28 to allow easy release
of air bubbles from below the porous membrane.
[0036] The inner wall of the inner holder 22 may also comprise a guiding groove 30 oriented
longitudinally, for both pipetting and TEER (Trans Epithelial Electrical Resistance)
electrodes. The guiding groove 30 may guide the tip of a pipette up to 1 mm above
the porous substrate 10 without touching the cell culture and membrane damaging. The
same groove 30 can be used to easily position reproducibly the electrodes used to
record TEER values.
[0037] As mentioned above, the support surface 16 of the lower support 12 may be equipped
with some antiwear means. For example, it may be coated with a suitable antiwear coating
or comprise an antiwear ring 31 (figure 1c). Teflon or other low friction polymers
are well suited as antiwear means.
[0038] To enhance the use of the insert according to the invention, figure 4 also proposes
a tool 32 designed to assemble/disassemble easily the inner holder 22 on the lower
support 12, reducing any risk of contamination or of wrong manipulation. Such tool
32 comprises a grip to be handled by a user or by a robot. Said tool 32 also comprises
some driving structures 34 able to cooperate with corresponding structures arranged
in the inner holder 22. Once the driving structures 34 are engaged with the corresponding
structures of the inner holder 22, one can tighten/untighten the inner holder 22 in
the lower support 12 by rotating the tool 32 in one or in the other direction, while
the lower support 12 is fixed. As shown in figure 4, the driving structure may be
obtained by screws or pins, while the corresponding structure may be obtained by grooves
realized on the top end of the inner holder 22. One can implement a torque limiting
system in the tool grip or between the grip and the driving structure, to avoid damaging
the substrate.
[0039] Other tightening means could also be considered. For example, figure 5 proposes to
assembly the inner holder 22 by clipping it on the lower support 12. To this end,
the inner holder 22 may comprise some elastic extensions 40, sized and shaped to hook
a rim 42 or the flanges of the lower support 12. The elastic properties of the extensions
allow, when the inner holder is hooked, to fix rigidly these two parts and to clamp
the porous substrate in between. The elastic properties allow however to unclip these
two parts.
[0040] Figure 6 proposes to assembly the inner holder 22 by screwing it on the lower support
12. Similarly to the embodiment of figure 5, the inner holder 22 may comprise some
extensions 40, comprising first screwing means 44 (i.e. thread or tapping), sized
and shaped to cooperate with second screwing means 46 (respectively tapping or thread)
of a rim 42 of the lower support 12. These two parts can be screwed in order to clamp
the porous substrate in between.
[0041] Thus, the insert according to the invention allows clamping a porous substrate 10
comprising a silicon nitride membrane supported on a silicon frame and obtained by
microfabrication, in an efficient and practical way. The holder is key to the use
of the porous substrate, the design of which can be tuned according to the most precise
requirements of the cell culture. One can therefore benefit from the advantages of
such a substrate, as detailed in the introduction. Indeed, despite the very tight
seal, the substrate can easily be removed after an experiment and can be reconditioned,
i.e. cleaned to obtain a bare porous substrate 10 and reused for a subsequent cell
culture. Furthermore, the assembling and disassembling procedure allows the membrane
to be turned upside down and still incubated with the physiological buffer. These
properties may improve the co-culture procedure. As explained above, the insert is
well suited for TEER measurements.
[0042] In a further improvement of the insert according to the invention, one could consider
integrating the relevant contact pads and circuits for TEER measurements. For example,
thanks to its silicon basis, the substrate could be provided with integrated electrodes.
The insert could also be equipped with contact pads designed to facilitate electrical
contact with the external equipment. This would greatly improve the reproducibility
of electrical measurements.
[0043] In another improvement of the insert, one could consider integrating a wave guide
in the inner holder 22, such wave guide being used to bring the light close the surface
bearing the culture cell, either for growth improvement or the illumination for optical
inspection or for preculture UV sterilization.
[0044] The examples above should not be considered as limiting. Those skilled in the art
will appreciate that numerous modifications can be made thereof without departing
from its spirit. The scope of the invention is to be determined by the appended claims
and their equivalent.
1. Clamping insert for cell culture comprising:
- a lower support (12) comprising:
i. a hollow member (14) sized to be engaged in a well of a microplate, said hollow
member (14) being open at both its ends and comprising a support surface (16) at one
of its ends,
ii. first tightening means,
- an inner holder (22) sized to be fitted inside the hollow member (14), and comprising
second tightening means arranged to cooperate with said first tightening means of
the hollow member (14) to tighten reversibly between the inner holder (22) and the
support surface (16) of the lower support (12) a porous substrate, said inner holder
(22) comprising an opened channel keeping free the porous substrate;
- retaining means (18) intended to cooperate with the well of the microplate to allow
the clamping insert to be suspended in the well of the microplate,
- sealing means (26) to hermetically seal the contact area between the clamping insert
and said porous substrate.
2. Clamping insert according to claim 1, characterized in that the inner wall of the inner holder (22) also comprises a guiding groove oriented
longitudinally, allowing passage of a pipette or of a TEER (Trans Epithelial Electrical
Resistance) electrode.
3. Clamping insert according to one of the previous claims, characterized in that sealing means comprise a seal interposed between the inner holder (22) and the porous
substrate and/or a seal interposed between the substrate and the lower support (12).
4. Clamping insert according to one of the claims 1 to 3, characterized in that said first and second tightening means form a bayonet fitting.
5. Clamping insert according to one of the claims 1 to 3, characterized in that said first and second tightening means form a screw fitting.
6. Clamping insert according to one of the claims 1 to 3, characterized in that said first and second tightening means form a clipping fitting.
7. Clamping insert according to one of the previous claims, characterized in that the inner holder (22) and/or the lower support (12) is/are made of PEEK, polycarbonate,
polystyrene or other plastics compatible with cell culture.
8. Clamping insert according to one of the preceding claims, characterized in that the retaining means are flanges (18) extending from the wall of the hollow member
(14) oppositely to the end comprising said support surface (16).
9. Assembly of a clamping insert as claimed in any of the preceding claims and a substrate
freely arranged and clamped between the lower support (12) and the inner holder (22),
so that the substrate can be removed from the insert only by untightening and disassembling
the inner holder (22) and the lower support (12).
10. Assembly according to claim 9, characterized in that the porous substrate (10) is made of Si3N4.
11. Assembly according to claim 9 or 10, characterized in that the porous substrate (10) is micromachined.
12. Assembly according to claim 11, characterized in that the porous substrate (10) comprises a silicon nitride membrane supported on a silicon
frame.
13. Assembly according to claim 12, characterized in that it integrates pads and electrical circuits for electrical measurements, in that the substrate is provided with integrated electrodes and in that the insert is equipped with contact pads designed to be in contact with the electrodes.
14. Method for clamping a porous substrate (10) with an insert as claimed in claims 1
to 8,
characterized in that it comprises the following steps:
- unfitting the inner holder (22) and the lower support (12),
- disposing said porous substrate (10) on the support surface (16) of the lower insert,
- disposing the inner holder (22) so as to clamp the porous substrate (10) between
the inner holder (22) and the lower support (12), and
- tightening the inner holder (22) with the lower support (12).
15. Method according to claim 14, characterized in that the step of tightening involves a dedicated tool (32) comprising some driving structures
(34) intended to cooperate with corresponding structures arranged in the inner holder
(22).